Electronic switching system



June 12, 1951 1.. s. GALSTAUN ET AL ,7

ELECTRONIC SWITCHING SYSTEM Ofiginal Filed Sept. 5, 1948 2 Sheets-Sheet 1 INVENTORS LIONEL 5. GALSTAUN BY EDWARD R. KEEVER AGENT June 5 1.. s. GALSTAUN ET AL ,7

ELECTRONIC SWITCHING SYSTEM Original Filed Sept. 5, 1948 2 She't's-Sheet 2 a? a k mg Q J ml IN V EN TORS LIONEL 5'. GALSDJUN EDWARD R. KEEVER Zwu rf/M AGE/VT Patented June 12, 1951 ELECTRONIC SWITCHING SYSTEM Lionel S. Galstaun, San Francisco, and Edward R. Keever, Martinez, Calif assignors to Tide Water Associated Oil Company, San Francisco, Calif a corporation of Delaware Original application September 3, 1948, Serial No.

1950, Serial No. 160,082

4 Claims.

This invention relates to distillation columns, and more particularly to means for automatically attaining desired reflux ratios during distillation and automatically changing the reflux ratio during critical periods of operation. The invention is primarily adapted for use in conjunction with batch stills of the type commonly employed in laboratory investigations, although it also has utility in certain commercial distillation operations especially Where close fractionation of product is desired.

It is an object of the invention to provide means for automatically maintaining a higher reflux ratio in'a distillation column during those periods when distillate product is changing and a lower ratio during those periods when the composition of the product is constant.

Another object is to provide automatic means to cut ofl, or diminish, the product draw-oil from a distillation column during periods of temperature rise.

An object of a specific embodiment of the invention is to provide means for coupling a thermocouple operated temperature recorder to the reflux ratio control apparatus of a distillation column to change the reflux ratio upon a change of temperature.

Other objects will be apparent from the following description.

In the laboratory investigation of mixtures of distillable liquids, and in certain commercial operations where such liquids are to be separated into components, it is common practice to distill these in a batch type still provided with an adequate distilling column containing packing, bubble plates, or other contact means. vapors from the top of the contact material are usually condensed and a portion thereof returned to the column to provide reflux while a second portion is withdrawn as distillate or product.

The ratio of the quantity of condensate returned to the column to the quantity of product withdrawn is termed the reflux ratio. In order to diminish the amount of labor, and to attain more uniform distillation, various equipment has been developed to control automatically the rate of distillation and to maintain a constant reflux ratio. Likewise, various automatic equipment is known for separating the distillate into cuts so that several products from the still can be segregated.

Depending upon the closeness of fractionation desired, the reflux ratio required may vary from 1:1 to as high as 20:1, or even higher. Even with highly efiicient fractionating columns, high reflux ratios are required when it is desired to The 53 Divided and this application May 4,

obtain a close fractionation of product such as is required for laboratory investigations or in the commercial separation of organic liquids of high purity. An especially high reflux ratio is needed during the period of transition of one product to another, whereas a substantailly lower reflux ratio may be used during those periods when the composition of the product is constant.

With an automatic still of the usual type, unless an attendant is present to adjust the reflux ratio as required, the reflux controls must remain set at the high ratio needed during product changes and the entire distillation must be conducted at this ratio. Consequently, the time nor-. mally required to complete a distillation in an entirely automatic still is far greater than when the reflux ratio can be reduced during periods of constant product composition.

In accordance with the present invention the reflux ratio of an automatic still may be set at the low value desired for constant product composition, and when the slightest change in composition occurs, the reflux ratio will be automatically doubled, tripled, or increased to any desired extent. After the composition of the product becomes constant again, the normal reflux ratio is automatically reestablished. It is thus seen that, by use of the invention, a large amount of time may be saved in the distillation of a batch of material in an automatic still.

The invention will better be understood by reference to the drawings, Figure 1 of which illustrates in diagrammatic form mechanical and electro-mechanical apparatus embodying principles of the invention.

Figure 2 is a schematic diagram illustrating a preferred form of electronic apparatus exemplifying features of the invention.

Referring to Figure 1, there is represented by the numeral I a sectional view of the head of a. laboratory type distillation column, which is equipped with finger type condensing coil 2 positioned to condense vapors which rise in head I and to direct the condensate into valve 3 and draw-off line 4. For controlling the reflux ratio, valve 3 is intermittently opened and closed by needle 5 which is operated by solenoid 6. When the circuit between terminals 1 and 8 is closed (as will be explained later) solenoid 6 is energized by current controlled by any suitable timing device, which is illustrated by cam 9, operated by clock-work It and actuating contact points ll. When the lobe of cam 9 depresses its follower, contact points II are closed permitting current to pass through solenoid 6 which, upon becoming thus energized, raises valve pin 5 opening valve 3 3 and causing liquid condensing on surface of coil 2 to be discharged through draw-off line 4. When the lobe of cam 9 passes beyond its follower, contacts ll open breaking the circuit to solenoid 6 and permitting pin to close valve 3. Whenvalve 3 is closed, the condensate is unable to enter line A and consequently drains down column head I and returns to the fractionating column (not shown) as reflux. It is apparent, therefore, that the reflux ratio of the column maybe set at any desired value depending upon the ratio of the length of periods during which contact points ll are open and closed.

Various timing devices are available on the market and the form depictedby'camQ, contact H and clock-work H3 is for the purpose of-simplicity of illustration and, per se, forms no part of the present invention. Likewise, still-head i, condensing coil 2, and valve 3 are illustrative ofa commonly used form of reflux control, but the particular design thereof shown in Figure l is merely for illustrative purposes to explain the operation of the invention.

In accordance with the invention, during periods when the product obtained from line 4 is changing in composition, the scheduled openings of valve 3 are interrupted thereby causing a greater proportion of condensate to be returned to the column as reflux, thus increasing'the reflux ratio at a time when high rates of reflux are desirable.

To this end there is sealed (or otherwise introduced) into column-head l a thermocouple i2 located at any point where control may be de- W s ed. The cold junction 53 of the thermocouple is positioned in a constant temperature bath (not shown) or a suitable cold junction compensating device is included in the thermocouple circuit. Terminals l4 and of the thermocouple are connected to a potential-balancing device, illustrated by slide-wide potentiometer IS, the slide ll of which is operated by worm l8 and motor Hi. In series with the thermocouple circuit there is placed a potential responsive means illustrated by galvanometer 2D, the needle of which operates contacts 2i and 22 depending, respectively, upon whether the temperature of thermocouple I2 is above or below that correspondingto the position of slide ll. Motor I9 is equipped with two windings so arranged that passage of current through one winding causes the motor to rotate in one direction and passage of current through the other winding causes the motor to rotate in the opposite direction.

Accordingly, should the temperature of therinocouple l2 rise above that corresponding to the electrical potential between slide l1 and terminal 23 of potentiometer l6, current will flow through'galvanometer 29 causing contact 2| to close and permit-current from battery '24 toflow through leads and 21 of motor l9 which will then rotate worm .l8 raising slide ll until a balance isre-established. Likewise, should the temperature of thermocouple I2 fall below that corresponding to the potential between slide I! and terminal '23, the current through galvanometer 2d will cause contact 22 to close, permitting current from battery 24 to flow through terminals 25 and 26 of motor l9. Motor [9 will then rotate worm [8 in the reverse direction lowering slide it until balance is established.

If desired, suitable relays of either the electro-mechanical or thermionic type may be introduced in the circuits of motor IQ for the purposeof reducing the currents handled by contacts cult controlled by contact-2 I.

4 2i and 22, or to control the direction of rotation in the event an ordinary reversible motor is substituted for motor l9.

A feature important to the operation of the invention is relay 28 which is included in the cir- It may be placed in series (as shown) or in parallel with motor terminals 25 and 21 as the characteristics of the current supplied by battery 24 may dictate. If desired, the current supplied to relay 28 may be amplified by suitable relays. Sufiice it to say,

for the-present, that the circuit is such that relay 2% will operate upon a flow of current through galvanometer'Z ilcorresponding to a rise in temperature of thermocouple l2.

'Itwill'be readily apparent to anyone familiar with the art o'f recording potentiometers that the balancing device depicted in Figure 1 by potentiometer HS, galvanometer 20, motor I9 and the described circuits is similar to well known types of recording and/or indicating potentiometers.

In fact, for the-purposes of the invention any type of balancing potentiometer may be substituted for galvanometer 20, potentiometer l6, and

motor i2, providing that provision is made to supply current to relay 28 dui'ing'any period when the temperature of thermocouple I2'is above that corresponding to the electrical-potential-of the balancing instrument.

The armature of relay'28 is's'o connected with a timing device, represented in Figure l by cam 29 operated by clockwork 30, that when relay 28 is energized, thus opening contact 3|,the latter will remain open for a predeterminedtime. As illustrated in Figure 1, this is accomplishedby pin 32 which normallyengages in-slot33 of cam 29 preventing clockwork'30from operating. Upon relay 28 becoming energized, pin'32 is withdrawn from slot 33 permitting *cam 29 to be rotated by clockwork 30. During rotation of cam 29, pin 32 rides on the surface of cam 29 holding contact 3| open until cam '29 makes one complete revolution and slot 33 is again in position tobe en- .gaged by pin 32, which engagement stops the clockwork until relay 28 is again energized. As seen in Figure 1, contact 3! opens the circuit to solenoid '6 from timer ll through terminals 1 and 8' thereby causing valve 3 to remain closed during the time required for one revolution of cam 29.

Preferably, clockwork '39 is so adjusted that the time for one revolution of cam' 29 isgreater than that for one revolution of cam 9, so that upon operation of relay 23 (which in turn is due to any rise of temperature of thermocouple I2) valve 3 will skip one scheduled opening, thereby doubling the reflux ratio. If desired, the timing of cam 29 can be adjusted to cause valve 3 to skip two or more scheduled openings upon actuation of relay- 28.

In some instances, especially where low reflux ratios are employed, it may be desired to decrease the time of rotation of cam 29, or to eliminate cam 29 entirely. In such cases valve 3 will be closed, contrary to its regular schedule, for only short periods with correspondingly small increase in reflux ratio.

Operation of the apparatus may be readily understood if itis assumed that head I is attached to the distillation column of a laboratory still in which a mixture of two hydrocarbons (for example, a mixture of benzene and toluene) is being distilled. The still may advantageously :be equipped with an automatic heater and control giving'an approximately constant boil-up rate,

Also, suitable automatic equipment may be supplied to segregate the distillate product from line 4 into desired cuts. Likewise, if desired, suitable temperature recording apparatus may be added, controlled either by a separate thermocouple or by the operation of slide ll of potentiometer l6. Vapors rising in head I are condensed on the surface of coil 2 and the condensate drains into valve 3. At the particular period depicted in Figure 1, valve 3 is open and the condensate is drawn off through line 4 to the receiving apparatus.

Timing cam 9 and clockwork H) are set for the reflux ratio to be maintained during periods of constant product composition, i. e. during periods of constant temperature at thermocouple l2. For example, a reflux ratio of 9: 1 may be chosen and cam 9 may be adjusted to close contact II for six seconds every minute. As cam 9 rotates from the position shown contact I l opens breaking the circuit to solenoid 6 and permitting pin 5 to drop into and close valve 3. Condensate from coil 2 will then be diverted to flow back down the column as reflux.

As long as the composition of the vapors in head I remain constant the temperature of thermocouple I2 will likewise remain constant and the electrical potential developed by the thermocouple at points l4 and [5 will be balanced by the potential between slide I1 and terminal 23 and no current will flow through galvanometer 20. Clockwork 30, will consequently, remain at rest, being held by the engagement of pin 32 in slot 33 of cam 29.

"Distillation will then proceed at the 9:1 reflux ratio during the recovery of the major part of the lighter constituent of the mixture being distilled, e. g. during the recovery of most of the benzene from a benzene-toluene mixture. As the distillation of the lighter component nears completion some vapors of the heavier component 1 (e. g. toluene) will reach head I causing a slight rise in the temperature of thermocouple l2 and causing current to flow through galvanometer 20. The needle of galvanometer 20 will accordingly close contact 2| permitting current from battery 24 to flow through relay 26 and terminals 21 and 25 of motor l9, which latter will rotate worm l8 and move slide H to a new position on potenti ometer l6 and thus re-establish a, potential balance with thermocouple l2. When relay 2-8 is energized, contact 3| will be opened and will remain open for one complete rotation of cam 29 which, for the example chosen, may advantageously be set to rotate in say 65 seconds which period is long enough to cause contact 3| to remain open during one closure of contact I l. Due to the opening of contact 3| no current can flow to solenoid 6 since the circuit is broken between terminals 1 and -8 and valve 3 will remain closed while contact 3| is open. Accordingly, valve 3 will be caused to skip one scheduled opening and will be open for only 6 seconds in two minutes, resulting in a reflux ratio of 1921. This procedure will be repeated as long as the temperature of thermocouple l2 continues to rise, that is until the lighter component has been completely distilled and the operation Of the still becomes stabilized on the heavier component.

Although for the purposes of illustration a two component mixture was used in the above example, it is obvious that the operation would be the same with a multi-component mixture. Each product of constant boiling point woud be distilled mainly at the reflux ratio determined by cam 9 with ail-approximately double reflux ratio during periods of product change, where high reflux ratios are desired.

It will be obvious from the above description that many variations of the apparatus shown in Figure 1 may be made within the spirit of the invention in its broadest scope. For example; clockwork l0 and/or clockwork 30 may be replaced by a motor of approximately constant speed, or other timing devices may be substituted for cams 9 and 29. Certain thermionic timing devices are known which are adaptable .to operate solenoid 6 in a manner similar to that described for timing device 9. Likewise, the opening of contact 31 may be caused to stop timing device 9 when contact H is open, instead of directly breaking the circuit to solenoid 6 at terminals l and 8. As stated above, various forms of balancing potentiometers may be used instead of the particular form illustrated. By the use of suitable apparatus, the opening of contact 31 may act directly to close valve 3 or a separate valve suitably located in line 4.

Figure 2 of the drawings illustrates a preferred variation of the potential balancing and reflux ratio changing apparatus embodying thermionic circuits. In Figure 2 there is illustrated in schematic form a thermocouple balancing potentiometer of the general type described in U. S. Letters Patent No. 2,150,006, issued to Parker and Aceves, comprising: thermocouple I2, D. C. to A. C. converter 50, two stages of amplification 5| and 52, and two-phase reversible induction motor 53, which operates worm l8 and slide 11 of slidewire potentiometer l6. Operation of the balancing system may briefly be described as follows:

In converter 50, metal reed 54 is caused to vibrate between the poles of magnet 55 in synchronization with alternating current supplied from source 56 which supplies current to coil 51. The vibrating reed 54 alternately closes contacts 58 and 59 connected to opposite sides of the split primary of transformer 60. The center tap of the primary of transformer 60 is connected to slide ll. One terminal of thermocouple I2 is connected to reed 54 and the other terminal of thermocouple I2 is connected to terminal 23 of potentiometer l6. Due to vibration of reed 54, any current in the thermocouple circuit caused by an out-of-balance position of slide I! will cause a current to flow alternately in one side and the other of the primary of transformer 60 resulting in an alternating potential in the secondary of transformer 60 which will be inphase or 180 out-of-phase with alternating current source 56 depending upon the direction of flow of current through thermocouple l2. After amplification the resulting potential of the output terminals BI and 62 of stage 52 will, likewise, be in-phase or 180 out-of-phase with source 56 depending upon the direction of current flow through thermocouple 12, which is dependent upon whether thermocouple I2 is at a higher or lower temperature than corresponds to the position of slide IT. The amplified current from stage 52 is fed to one winding of twophase motor 53, the other winding being supplied with alternating current from source 64 which is in synchronization with, but out-of-phase with, source 56. Accordingly, motor 53 is caused to rotate in one direction or the other depending upon whether the temperature of thermocouple l2 is above or below that corresponding to the slide [1. The resulting rotation of motor 53 causes slide [1 to move correspondingly along potentiometer ii-"and: re establi'sh balance in the thermocouple circuit.

:As isobvious to one familiar with electronic art, stages 5l, and 52 may be either'transformer coupled (as-shown, for simplicity of illustration) or they may be resistance coupled. The plate circuits may be fed by battery (as shown) orby alternating current through suitable rectifying means. Likewise, othertypes of convertersm'ay be substituted for converter 50. 'In one well known .potentiometer-recorder on the market, known :as the f Bro'wn "Electronik Continuous- Balance Potentiometer Pyrometer, stage 52 comprises twin dio'des whose plate circuits are supplied with alternating current through as-plit secondary of a transformer whose primary is supplied from source 56. 'In this instrument the phase of the current from 61 and 52 is "shifted 90 sby use of suitable condensers -(not shown) and'thelcurrent supplied to motor 53'frorn source :64. is of the same phase as source 56, a11 of which is well known in the potentiometer art. Suflice itto :say thatffor'thepurposes of the variation ofithe invention illustrated in Figure fl, one winding of motor 53 is supplied with alternating'current'which lags or leads the alternatingcurrent supplied to the other winding by substantially 90 depending upon the direction of the flow of :currentin thermocouple 12.

For thepurposes'o'f the int QljlOIl is provided transformer G-figwhioh may adv stagedhave a 1:1 ratio, the primary of which isc nectedto the-output leads ili and 62 of amplifier stage 52yan'cl the secondary is connected to the control :gridv of thyratron tetrode A positive cathode bias, indicated by'battery ii'i, is provided of sufficient potential to prevent-ap current in this tube. ills'anexamplepcathodebaasiel advantageously be. from 6 to 15 volts, preferabl about volts. The plateiof tubeee .is-supplicd with alternating potential from the secondary of transformeriit, theprlmary of which is connected-to'source :In the zplate'circuit'of tube 66 there'are included contact iii of two-pole relay l0 and'thecoil of relay'lZ.

Tube 'l l'is a powertube, which may advantageously be of the pento'de or beampow'er2ampliiler types, the plate-circuit controllingtheoperation of relay The control grid circuit includes, in seriea'contact isof relay i l and negative grid representedby battery h-of sufii cient'voltage to prevent tube i l-from conducting when contact is closed. ricross thewcontrol grid of tube l' ltherearelplaced condenser TE and variable resistance it of 'sum ient size to m'aintain a negativecharge on the control grid of tube H for a desired-period of tlmeafter :contact l3 is opened.

Contact ll of relay l? ispiaced in is "ies with the reflux timing circuit illustr ted in Figure l and takes the place or" contact-3i of-relay 28in Figure l.

The operation or the circuits of tubes E6 and '14 is asfollows:

When the potential developed by thermocouple I2 is balanced by potentiometer lfi'no alter- 'nating "current ls-developed in'the output terini- 'nalsiii an'dt?! of stage 52 andno potential-is developed by the-secondary-of transformer During such times tube 1 is cut 01%" due to positive cathode'bias -Eil. Contact i=3 of relay 'lfi will then be open due to'no' current ilowing in "the plate'circuit oitube With contact 73 open, the controligrid of tube i l is at Zero potential relative .toiits cathode permittingtube M to con- $2. condenser l5, tube 14 will remain out-oli until 'ing of contact 13.

duct land current will. pass through the coilof relay 'lll' closing'contacts 69 and l l When thetmpera'ture-of thermocouple 12 is belowthe corresponding position of slide H, i. 0. during periods when the temperature of thermocouple l2 may be'falling, an alternating potential produced at terminals =6 l and S2 producing alternating potential at the terminals of the. secondary of transformer 65. However, the

.potentialso produced on the grid of tube 65 will be cut'oi' phase with the potential produced on the plate of tube 56 bythe secondary of transiormerfi Conseouently, tube 56 will still be unable to'conduct since its plate will be negative when its grid is positive and when the plate is positive the grid will be negative 'I-Iowever, during'periodswh .1 the temperature of thermocouple i2 is rising, thepotential pro- .du'ced by-the-secondary oi transformer 65 will be-inephase with that produced by the secondary of'transformer 63 andtube 66 will conduct per mitting current to pass throughrelay 12, thereby closing contact '53. Upon closure of'contact 13 a negative grid'bias is established on tube "i4 outting-off this tube and simultaneously charging condenser l5. When-tube "i l is so cut-off, current ceases to flow in relay 10 opening contacts 69 and "El. Opening of contact 63 cuts off the flow of current in tube-G6 ancl'opens contact 13 of relay However, due to the charge accumulated on this charge leaks off throughvariable resistance it, after which tube "l4 again conducts and relay if) closescontacts t9 and ll returningthe system to normal operation.

Since contact 'H is in series with the timing circuit of-solenoid E (Figure 1) the latter'will remain inoperative valve 3 will remain closed as long ascontact ll is open. By proper choice of the characteristic of condenser 15 and proper setting of resistancelfi, the. length of time that contact His open can-be regulated to cause valve 3 to missone or more scheduled openings, therebyincreasing the reflux ratio by double or more.

in commercial instruments of the type depicted by-converter Bil amplifiersfil and. 52, and motor 53, the output o1 amplifier-52 may a1so,.even at conditions of balance, contain a component of twice the frequency of-source 53. phase of the output of stage 52 may purposely lag Likewise, the

the'phase of source 56 to permitproper operatlon of motor In such cases the secondary of transformer 65 may be tuned to passonly the frequency of source 56 and the phase may be corrected by the addition of condenser 18 and/or resistance 1'! across the secondary of transform or 65.

"Also/in commercial instruments stray ortran- 'sient electrical impulses may be generated of sufficient magnitude to triggertube '36. be compensated by the addition of resistance 19 This may in the grid circuit of tube 14 to slow down the rateof charge of condenser 15 sufiicient that and 19, and for condensers l8 and 86 can readily :be I determined by one skilled in the electronic art with the aidof the above descripiton.

summarizing the "above descriptions of Figures '1. and-2, thel-invention,inits broadest 'as- .pects may comprise either -mechanical, electromechanical, or thermionic means for (a) balancing a thermocouple established in a distilling column, and (b) setting in motion a timing device arranged to increase the reflux ratio of the column for a predetermined period upon any rise of temperature in the column. Various modiiications will suggest themselves to the technician within the scope and spirit of the invention as set forth in the appended claims.

This application is a division of our copending application Serial Number 47,728, filed September 3, 1948.

We claim:

1. Apparatus adapted to control an electric circuit for a desired period of time upon a change in one direction of electric potential in a pilot circuit, comprising; a source of alternating current; a pilot circuit including thermocouple terminals, balancing means to balance the potential across said terminals, and a converter adapted to convert an unbalanced potential in said pilot circuit to an alternating current of the same frequency as said source and of a phase dependent upon the direction of said unbalanced potential; amplifying means for the resultant alternating current; balancing means operated by the resulting amplified alternating current to rebalance said balancing means; a thyratron obtaining its plate voltage from said source; means in the input system of said thyratron connected to the output of said amplifying means to energize said thyratron when the potential of said output is in phase with said source; a power tube including in its input system a time-delay con denser and resistance; means connected to the output system of said thyratron to cut off said power tube and charge said condenser; means in the output system of said power tube to open the output circuit of said thyratron upon said power tube being cut off; and means in the output sys tem of said power tube to control another electrical circuit upon said power tube being cut off.

, 2. A thermionic timer for an electric circuit actuated by difference in phase of two control circuits comprising: a thyratron whose, plate circuit is adapted to be energized by a first source of alternating current, means in the input system of said thyratron to supply a suflicient cathode bias to render said thyratron normally non-conductive, means in the input system of said thyratron to impress an alternating potential from a second alternating current source of sufficient strength to overcome said bias and render said thyratron conductive when said second source is in phase with said first source, a power tube whose plate circuit is adapted to be supplied with a source of direct current sufficient to render said power tube normally conductive, relay means in the output of said thyratron adapted to impress a negative grid bias upon said power tube when said thyratron conducts, a condenser bias and a resistance leak in the input system of said power tube adapted to retain said negative grid bias for a predetermined time, relay means in the output system of said power tube adapted to open the plate 10 circuit of said thyratron when said power tube is not conducting, and relay means in the plate circuit of said power tube to control a desired controlled electric circuit.

3. In combination with a thermocouple balancing potentiometer of the type which is balanced by a motor controlled by amplified alternating current of the same frequency as a source current but differing in phase with said source current depending on the direction of any unbalance in the thermocouple circuit, control apparatus comprising: a thyratron whose plate is energized by said source current, means in the input system of said thyratron to render same normally non-conductive, means connecting said amplified alternating current to the input system of said thyratron to render the same conductive when said amplified alternating current is in phase with said source current, means in the output system of said thyratron to trigger a thermionic timer, means in the output of said thermionic timer to re-set said thyratron, and means in the output of said timer to control a desired electric circuit.

4. In apparatus adapted to control the reflux ratio of a distillation column by alternating current signal from a balancing potentiometer, the combination of the following: two thermionic tubes each having a grid circuit and a plate circuit, a first transformer the primary of which is adaptable to receive signals from a balancing potentiometer, a second transformer the primary of which is adaptable to be connected to an alternating current source, a first relay actuated by the plate circuit of the first of said tubes, a second relay actuated by the plate circuit of the second of said tubes, connections to apply a positive cathode bias to said first tube, connections including the secondary of said first transformer in the grid circuit of said first tube, connections permitting the secondary of said second transformer to supply the plate current of said first tube, a bias condenser and resistance leak in the grid circuit of said second tube, means actuated by said first relay to apply a negative grid bias to said second tube and to charge said condenser, means actuated by said second relay to open the plate circuit of said first tube, and relay means associated with the plate circuit of said second tube to open and close another circuit in concurrence with the flow of current in said plate circuit.

LIONEL S. GALSTAUN. EDWARD R. KEEVER.

REFERENCES CITED The following references are of record in the file of this patent:

UNITED STATES PATENTS Number Name Date 2,261,172 Brown Oct. 24, 1944 2,373,516 Rechton Mar. 27, 1945 2,422,020 Kingsmill June 10, 1947 2,473,640 Faulk June 21, 1949 2,507,377 Matthias May 9, 1950 

